DE19539154A1 - Operation of heat and cold pumps - Google Patents

Abstract

The process uses at least two adsorbers each with a heat exchanger surrounded by the adsorption unit, at least one heat exchanger for high temperatures, one for medium temperatures and one for low temperatures. There is a pump for the fluid which goes first to the adsorbing heat exchanger, then to the high temperatures heat exchanger, then through the desorbing heat exchanger, then to the medium temperature heat exchanger, then again to the adsorbing heat exchanger. After the depletion of the adsorption mass, the fluid flow direction is reversed for a new charging and discharging period and the adsorption/desorption temperature regimes are at least partly overlapped.

Description

The invention relates to a method according to the preamble of claim 1 of the main application for with solids, such as Silica gel, active alumina, activated carbon, carbon molecular sieves and preferably working with zeolites as adsorbents Heat pumps, chillers and heat transformers, taking the description for simplification only on heat pumps and Chillers related. Liquids can be used as the heat transfer fluid and gases, especially air, are used. As Working medium can preferably be steam. The The process is structured and operated in such a way that a "hot" and a "cold" side of the two adsorbers.

The operation of a test facility has shown that the temperature of the heat transfer stream emerging from the desorber is steady rising course and the temperature of the from the adsorber escaping heat transfer stream a steadily falling course showed.

The invention specified in claim 1 is the object based on the temperature of the exiting from the desorber Heat transfer flow as low as possible, and the temperature of the the heat carrier flow exiting the adsorber is as high as possible hold, whereby the heat of the heat transfer circuit in the desorber  largely for desorption and the heat of adsorption in the adsorber largely used for preheating the heat transfer circuit becomes. The heat pump is also supposed to be on even with a high temperature rise deliver good heat ratio. The heat flow in the material of the Heat exchanger should be in the flow axis of the heat transfer fluid be kept low even with a short overall length.

Claim 1 gives the basic procedural Solution.

An embodiment of the invention is described in claim 2. The features of claim 2 make it particularly good Part of the adsorber can be cooled on the cold side. As a result, this part of the adsorber has even after switching to Desorber a low temperature and thus enables one particularly good use of the heat of the heat transfer circuit Desorption.

A further embodiment of the invention is in claim 3 described. Due to the features of claim 3 particularly high heating of a part of the desorber on the hot Side possible. As a result, this part of the desorber also has after Switching to adsorber a high temperature and enables one particularly high heating of the heat transfer circuit. Through the Features of claim 3 is the at high temperature strokes Heat pump where the temperature does not overlap advantageous operation is possible.  

A further embodiment of the invention is in claim 4 described. Due to the features of claim 4 Heat flow in the material of the adsorber heat exchanger in the Flow axis of the heat transfer stream even with small lengths kept low.

Further details, features and advantages of the invention emerge from the explanations below for the drawing.

It shows:

Fig. 1 is a compilation of the method according to the invention.

The process essentially consists of the two adsorbers 1 and 2 , the heat exchanger for high temperature 3 , the heat exchanger for medium temperature 4 , pipes, fittings and the conveying device for heat transfer fluid P. The lines 51 and 61 lead to the condenser or evaporator.

The heat transfer fluid is conveyed in a known manner with the conveying device P via the adsorber, for example 2 , the heat exchanger for high temperature 3 , the desorber, in example 1 , the heat exchanger for medium temperature 4 and again to the conveying device P. After the adsorber has been exhausted, the conveying direction of the heat transfer fluid is reversed in a known manner.

In the description below, only one half cycle described, since the other is carried out completely analog.  

The additional circuit proposed with claim 2 flows from the heat transfer circuit 22 for cooling the adsorber 2 via line 80 and the 3-way valve 81 to line 42 , in which it combines with the heat transfer circuit again and in particular together with the heat transfer circuit in the heat exchanger emits heat for medium temperature 4 , and is then conveyed to the adsorber 2 again via the four-way valve 41 , the function of which can also be provided by two three-way valves, from which it is drawn off again via the line 80 , which means that it is withdrawn again the cycle closes.

Another indirect cooling can also be provided in that, for example, a fluid flows through the heat exchanger available for the heat carrier circuit or through a third heat exchanger installed in the adsorber in order to obtain medium-temperature heat. A heat exchanger for 3 and more fluids is state of the art in plate-fin heat exchangers and is indicated with the cable line 82 . The third heat exchanger is useful when heat of medium temperature is to be transferred to a fluid other than that used for the heat transfer circuit.

The heat transfer medium for the additional cooling is preferably withdrawn from the adsorber 2 at less than the maximum outlet temperature of the heat transfer medium circuit emerging from the desorber 1 . This temperature depends on several factors, in particular the temperature difference between the condenser and the evaporator, which is why it is expedient to provide a plurality of draw-off points on the adsorbers which can be shut off in the figure as an example.

In order to heat the adsorber to the highest possible temperature To transfer desorber, it is useful to take the heat off the cold part of the adsorber to start at the end of the period and the circulation quantity of the heat transfer circuit via adsorbers and reduce or make desorber zero.

The additional circuit proposed with claim 3 is withdrawn with the conveying device P1 via the line 45 and the three-way valve 46 from the heat carrier circuit flowing in the hot part in the example of the desorber 1 and flows again via the three-way valve 47 into the heat carrier circuit with which it is in the heat exchanger for high Temperature 3 is heated, after which it flows through the hot part of the desorber 1 back to the trigger point, where the circuit closes. It is also possible to use two conveying devices, each with a backflow preventer, instead of the conveying device for fluid and two three-way fittings.

Other heat sources can be, for example, steam, hot oil, hot exhaust gases or a radiant heat source, the heat of which can be transferred to the hot part of the desorber via a third heat exchanger. A heat exchanger for 3 and more fluids is state of the art in plate-fin heat exchangers and is indicated with the cable 48 .

The required area of the desorber 1 , which is additionally heated, depends on several requirements. Therefore, this area is preferably designed to be variable, which is indicated by the two lockable deductions for heat transfer fluid from the desorber 1 . By providing a larger area of the desorber, which is additionally heated, heat pumps and chillers can still be operated advantageously with the method according to the invention even when the temperature rise is so large that an overlap of the temperatures of the adsorber and desorber is no longer possible.

Individual parts of the adsorber 2 are shown in FIG. 1. According to claim 4, the outer walls 29 , the sieve or perforated plate 27 and required other internals made of material with a particularly low thermal conductivity, for. B. also made of stainless steel. The fins in the heat exchanger for heat transfer fluid 22 and in the heat exchanger 24 built into the adsorber material 23 , which must have the best possible thermal conductivity, receive interruptions perpendicular to the flow axis of the heat transfer fluid. The fins in the heat exchangers are shown offset. The fins of both heat exchangers are connected with their feet 26 opposite to the partitions of the heat exchangers. The partition is made of material with little less thermal conductivity than that of the fins. The deterioration of the thermal conductivity through the use of alloyed base material is sufficient.

Supplement to the main application.
It has been found that compact heat exchangers can be produced economically from extruded tubes with finned tubes on both sides. An application is made to include extruded tubes with ribs on both sides in the description of the main application.

Claims (4)

1.Procedure for the operation of heat pumps and chillers consisting of at least two adsorbers, each with a built-in heat exchanger surrounded by adsorbent, at least one heat exchange device for high temperature, at least one heat exchange device for medium temperature and at least one delivery device for a heat transfer fluid, the fluid initially passing through the Heat exchanger of the adsorbing adsorber is then conveyed through the heat exchanger for high temperature and then through the heat exchanger of the desorbing adsorber, after leaving it passes the heat exchanger for medium temperature and then flows back to the heat exchanger of the adsorbing adsorber, after exhausting the adsorption mass in the adsorbing adsorber the direction of flow of the fluid is reversed for a new loading or unloading period, and the adsorption and desorption temperatures change Oak at least partially overlap, and modified compact heat exchangers are used as heat exchangers and in particular adsorber heat exchangers, characterized in that part of the respective adsorber is additionally cooled by the heat transfer circuit for cooling and / or part of the respective desorber is additionally heated for heating by means of a heat transfer circuit . 2. The method according to claim 1, characterized in that the respective adsorber in addition to cooling by the Heat transfer circuit through an additional circuit and / or through other indirect cooling is cooled, the heat output the additional circuit and / or indirect cooling and cooled portion of the adsorber can be varied to zero, and the additional circuit preferably with the conveyor for Heat transfer fluid (P) is promoted and preferably temporally is varied. 3. The method according to claim 1 and 2, characterized in that the respective desorber in addition to heating by the Heat transfer circuit through an additional circuit and / or through other indirect heat is heated, the heat output the additional circuit and / or the other indirect heat supply and the heated portion of the desorber can be varied to zero can and the heat supply is preferably varied over time. 4. The method according to claim 1 to 3, characterized in that the Partitions, which the space for adsorber solids and Working fluid from the room for the heat transfer fluid or fluids separate and necessary internals and external walls, made of material are produced with relatively poor thermal conductivity and Ribs in the room for adsorber material and heat transfer fluid preferably have breaks and largely opposite to be ordered.